Continuously variable speed transmission and steering differential

ABSTRACT

The present concept is a continuously variable speed transmission and steering differential. It includes a laterally extending central drive axle driven by an external power source, two pairs of drive sheaves mounted to drive axles, and a means for transmitting rotational energy from the drive sheaves to the drive axles. There are two extended shift arms spaced apart for controlling the positioning of movable drive sheaves. Narrowing or increasing the gap between shift arms, does the same for the gap between the drive sheaves, increasing or decreasing the gear ration respectively which provides speed control. Shifting the shift arms left or right varies the gear ratio between the left and right pair of sheaves, providing differential speed between the left and right driven axles, which provides steering control.

This application claims is a continuation of regularly filed application Ser. No. 14/718,983 titled CONTINUOUSLY VARIABLE SPEED TRANMISSION AND STEERING DIFFERENTIAL under the name Shawn Watling on May 21, 2015.

FIELD OF THE INVENTION

The present concept relates to continuously variable transmissions and more specifically relates to a continuously variable speed transmission combined with a steering differential.

SUMMARY OF THE INVENTION

A continuously variable speed transmission and steering differential having a central drive axle, two pairs of sheaves and two shift arms. The drive axle is driven by an external power source. The two pairs of sheaves, left and right, are mounted to the drive axle. Each pair of sheaves includes a fixed drive sheave and a movable drive sheave. Each movable drive sheave is positioned by a shift arm. Shifting the shift arms left or right varies the gear ratio between the left and right pair of sheaves thereby providing steering control. Narrowing the distance between the shaft arms increases the gear ratio and consequently puts the transmission into a higher gear, thereby providing speed control.

The present concept is a continuously variable speed transmission and steering differential comprising:

-   -   a. a laterally extending central drive axle rotatably driven by         a power source;     -   b. two pairs of drive sheaves namely a left and right pair,         mounted to the drive axle; wherein each pair of drive sheaves         includes a fixed drive sheave and a laterally moveable drive         sheave along the drive axle;     -   c. a means for transmitting rotational energy from the left         drive sheaves to a left driven axle and from the right drive         sheaves to a right driven axle;     -   d. two spaced apart longitudinally extending shift arms         connected to the moveable drive sheaves for controlling the         positioning of the moveable drive sheaves;     -   e. wherein narrowing or increasing the gap between the shift         arms narrows or increases respectively the gap between each pair         of drive sheaves and increases or decreases the gear ratio which         increases or decreases the speed of the driven axles, thereby         providing speed control;     -   f. wherein shifting the shift arms either left or right varies         the gear ratio between the left and right pair of sheaves which         provides differential speed between the left and right driven         axles thereby providing steering control; therefore speed         control and steering control is simultaneously and independently         effected by controlling the position of the shift arms.

Preferably further including;

-   -   a. the transmitting means includes two pairs of driven sheaves         namely a left and right pair, mounted to the left and right         driven axles respectively rotationally connected to the left and         right pair of drive sheaves respectively;     -   b. wherein each pair of driven sheaves includes a fixed driven         sheave and a moveable driven sheave such that the gap between         the pair of driven sheaves changes inversely proportionally to         the gap of the pair of the corresponding drive sheaves.

Preferably wherein the shift arms are longitudinally extending spaced apart parallel members.

Preferably wherein the shift arms are planar bars.

Preferably wherein the shift arms are connected with at least one ball screw shaft extending perpendicular to the shift arms for controlling the lateral spacing between the shift arms by rotating the ball screw shaft.

Preferably wherein the shift arms are connected with two spaced apart ball screw shafts extending perpendicular to the shift arms for controlling the lateral spacing between the shift arms by rotating the ball screw shafts.

Preferably wherein the ball screw shaft rotation is motor driven.

Preferably wherein the ball screw shaft is motor driven with sprockets mounted onto the end of each ball screw shaft and motor and inter-connected with a chain.

Preferably wherein further including a pivoting differential arm shaft connected to each shift arm with differential links such that pivoting the differential arm shaft in one direction varies the gear ratio between the left and right pair of sheaves and pivoting in the opposite direction varies the gear ratio oppositely between the left and right pair.

Preferably wherein the differential arm shaft is connected to at least one differential arm which in turn is connected to a link arm pivoting about a link arm pivot, wherein each end of the link arm is connected to one end of a differential link thereby connecting the differential arm shaft to the shift arms.

Preferably wherein the inner drive sheaves are fixed and the outer drive sheaves are moveable, and the inner driven sheaves are moveable and the outer driven sheaves are fixed.

Preferably wherein differential arm connected to a steering linkage which in turn is connected to a steering control such that actuating the steering control pivots the differential arm thereby providing steering control.

Preferably wherein the drive axle includes a cog pulley connected to a belt for receiving power from a power source.

Preferably wherein the drive axle includes a cog pulley connected to a belt for receiving power from a power source.

Preferably wherein the driven axles are connected to wheels.

Preferably wherein the driven axles are connected to tracks.

Preferably wherein the steering control is a set of pivoting handle bars.

Preferably wherein the power source is an internal combustion motor.

Preferably wherein the transmitting means further includes two v-belts rotationally connecting the left drive sheaves to the left driven sheaves and the right drive sheaves to the right driven sheaves.

BRIEF DESCRIPTION OF THE DRAWINGS

The present concept will be described by way of example only with reference to the following drawings in which:

FIG. 1 is a schematic cross plan view of the continuously variable speed transmission and steering differential with the steering shown in the straight position.

FIG. 2 is a schematic cross plan view of the continuously variable speed transmission and steering differential with the steering shown in the right turned position.

FIG. 3 is a schematic cross plan view of the continuously variable speed transmission and steering differential with the steering shown in the left turned position.

FIG. 4 is a schematic cross plan view of the continuously variable speed transmission and steering differential shown in the lowest gear position.

FIG. 5 is a schematic cross plan view of the continuously variable speed transmission and steering differential shown in a medium gear position.

FIG. 6 is a schematic cross plan view of the continuously variable speed transmission and steering differential shown in the highest gear position.

FIG. 7 is a schematic top plan view of the continuously variable speed transmission and steering differential shown together with the driven pulleys mounted on the driven axles as well as the ball screw actuator for moving the floating arms relative to each other.

FIG. 8 is a schematic back plan view of another embodiment of a continuously variable speed transmission and steering differential shown together with drive sheaves and driven sheaves, shown in low gear.

FIG. 9 is a partial top schematic cross sectional view of the embodiment shown in FIG. 8 taken through the drive axle showing the drive sheaves, the shifting mechanism, and the differential mechanism.

FIG. 10 is a top plan view of the embodiment shown in FIG. 8.

FIG. 11 is a schematic back plan view of the embodiment in FIG. 8 shown in high gear.

FIG. 12 is a schematic back plan view of the embodiment in FIG. 8 showing a maximum differential left turn.

FIG. 13 is a schematic back perspective view of the embodiment shown in FIG. 8.

FIG. 14 is a front schematic perspective view of the embodiment shown in FIG. 8.

FIG. 15 is a top plan view of the continuously variable speed transmission and steering differential together with a propulsion motor and handle bars.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present concept a continuously the continually variable speed transmission and steering differential shown generally as 100 in FIGS. 1 through 7 and includes the following major components.

The major frame members 101 include the centre chassis support 102 having mounted on each side thereof a right floating arm 104 and a left floating arm 106. Mounted near the rear section 103 of continuously variable speed transmission and steering differential 100 is drive axle 108 which has mounted thereon left fixed drive sheave 110, left floating drive sheave 114, right fixed drive sheave 112, and right floating drive sheave 116.

Not shown in FIGS. 1 to 6 however shown in FIG. 7 is drive sprocket 202 which is mounted onto drive axle 108 which receives power from for example an internal combustion engine and/or from an electric engine and transmits that power to the drive axle 108 through drive sprocket 102. In other words power is received from an external power source such as an internal combustion engine or an electric engine via drive sprocket 202 which drives drive axle 108. The reader will note that the left and right drive sheaves are connected to a common drive axle 108 which is mounted with bearings to centre chassis support 102 as well as right floating arm 104 and left floating arm 106.

Looking now to forward section 105 of continuously variable speed transmission and steering differential 100 there are two half shafts mounted onto the centre chassis support 102 and right and left floating arms 104 and 106 namely right driven axle 118 and left driven axle 120. Right driven axle 118 is mounted onto right finger 111 of centre chassis support 102 and also onto right floating arm 104 using bearings typically known in the art.

Similarly left driven axle 120 is mounted onto left finger 113 of centre chassis support 102 as well as onto left floating arm 106 again using bearings typically used in the art.

Right driven axle 118 and left driven axle 120 rotate independently of each other. It is the difference in speed of the rotation between right driven axle 118 and left driven axle 120 which provides steering response.

The gap or the distance between right floating arm 104 and left floating arm 106 is controlled and actuated by rear ball screw shaft 134 which is attached to rear ball screw nut 136 and front ball screw shaft 130 which is attached to front ball screw nut 132. The biasing means shown in the diagrams is a ball screw type advancing and retraction means however other biasing means for regulating the gap or the distance between right floating arm 104 and left floating arm 106 could for example be carried out with hydraulic or pneumatic cylinders or other mechanical advancement and retraction means which are known in the art. The absolute gap between right floating arm 104 and left floating arm 106 controls the gear position or the speed at which the right driven axle 118 and the left driven axle 120 are driven at.

Right driven axle 118 includes right floating driven sheave 128 and right fixed driven sheave 124. Left driven axle 120 includes left fixed driven sheave 122 and left floating driven sheave 126.

The position of centre chassis support 102 relative to both the right floating arm 104 and the left floating arm 106 is controlled by moving differential bell crank 142 which in turn moves differential rocker 138 which in turn urges differential rocker link 140 thereby varying the relative gap between firstly right floating arm 104 and centre chassis support 102 and secondly between left floating arm 106 and centre chassis support 102. Steering push rod 150 which is connected at one end to a steering wheel and/or handle bar is not shown and is connected at the other end to differential bell crank 142 which pivots about bell crank pivot point 144 thereby actuating differential rocker links 140 which in turn move right floating arm 104 and left floating arm 106 in opposite directions relative to centre chassis support 102.

Referring now to FIG. 7 you will note that 2 additional pulleys are shown which are not depicted in FIGS. 1 through 6 namely right driven pulley 208 mounted onto right driven axle 118 and left driven pulley 210 mounted on left driven axle 120. Right and left driven pulleys 208 and 210 would ultimately be connected via belts or chains or other known means to for example the drive wheels or the drive track of a vehicle. It is contemplated that the vehicle would have separately or independently driven left and right wheels or tracks. In this way the speed of the vehicle is controlled by the rate of rotation of right driven pulley 208 and left driven pulley 210 and steering is accomplished by varying the relative rate of rotation of right driven pulley 208 relative to left driven pulley 210. For example by driving right driven pulley 208 faster than left driven pulley 210 one can accomplish a left turn. By driving left driven pulley 210 more quickly than right driven pulley 208 one can accomplish a right turn.

Additionally an example of an actuation method for activating rear ball screw shafts 134 and front ball screw shafts 130 is shown. Namely a ball screw actuator 204 which could be in the form of a stepper motor or other known method of activation in the industry would be connected by a sprocket and chain to front ball screw sprocket 212 and a rear ball screw sprocket 214 to rotateably urge rear ball screw shaft 134 and front ball screw shaft 130 thereby varying the gap or the relative distance between right floating arm 104 and left floating arm 106.

FIG. 7 also shows a belt 206 in position mounted onto right driven sheaves 124 and 128 as well as onto left drive sheaves 112 and 116. Ball screw actuator 204 through a gearbox 254 drives front and rear ball screw chains 216 and 217.

In FIG. 7 for example the rear section 103 drive sheaves are shown in open position whereas the forward section driven sheaves 128 and 118 are shown in a relatively closed position. This would correspond to a low gear position of the continuously variable speed transmission.

Referring now to FIGS. 1, 2 and 3 which show three example positions for steering.

Referring now to FIG. 1 the centre chassis support is centred relative to both the right floating arm 104 and the left floating arm 106. In this position both the left and the right driven sheaves are turning at approximately the same rate of rotation and therefore the steering of the vehicle is approximately straight.

Referring now to FIG. 2 the reader will note that by rotation of differential bell crank 142 which in turn urges differential rocker links 140 to displace right floating arm 104 closer to centre chassis support 102 and displaces left floating arm 106 further away from centre chassis support 102 thereby causing the various sheaves to open and close relative together as shown in the drawings thereby creating a right turn condition.

FIG. 3 shows the positioning of the centre chassis support 102 relative to right floating arm 104 and left floating arm 106 creating a left turn condition.

In this manner the reader will note that by pivoting differential bell crank 142 with for example a steering push rod 150 one can accomplish a straight steering condition or a right turn steering condition and/or a left turn steering condition by simply moving the right floating arm 104 and the left floating arm 106 relative to the centre chassis support 102 thereby altering the gap between the sheaves of both the rear section 103 and the forward section 105 as shown in drawings 1, 2 and 3.

Referring now to FIG. 4 gear selection is accomplished by altering the gap and/or the relative distance between the right floating arm 104 and the left floating arm 106.

For example in FIG. 4 there is a minimal gap between right floating arm 104 and left floating arm 106 and this is accomplished by turning rear ball screw shaft 134 and front ball screw shaft 130 such that the right floating arm 104 and the left floating arm 106 come in as close as possible in proximity to each other. This would represent a low gear position in that the rear section 103 drive sheaves are as open as possible whereas the forward section 105 driven sheaves are in as closed position as possible thereby creating a lowest gear or slow position.

Referring now to FIG. 5 the rear ball screw shaft 134 and the front ball screw shaft 130 have been advanced such there is now a greater gap and/or relative distance between right floating arm 104 and left floating arm 106 thereby closing the gap between the rear section 103 drive sheaves and simultaneously slightly opening the gap between the forward section 105 driven sheaves thereby creating a greater rotational speed at both the right driven axle 118 and the left driven axle 120 which are ultimately connected to the drive wheels and/or tracks of the vehicle.

Referring now to FIG. 6 once again the rear ball screw shaft 134 and front ball screw shaft 130 are actuated to increase the relative distance or the gap between the right floating arm 104 and the left floating arm 106 to a maximum position which represents the highest gear wherein the gap between the rear section 103 drive sheaves is minimized and the gap between the forward section 105, driven sheaves is maximized thereby creating the greatest rotational speed of the right driven axle 118 and the left driven axle 120. This would be the highest gear position to produce the maximum speed condition.

I now refer the reader to FIGS. 8 through 15 a second embodiment shown generally as 300 of the continuously variable speed transmission and steering differential. Another embodiment of the present concept a continuously variable speed transmission and steering differential is shown generally as 300 and includes the following major components namely; drive axle 302 which is fixed to the chassis and rotates on bearings.

Drive axle 302 has mounted thereon left and right moveable drive sheaves 304, left and right fixed drive sheaves 306, left and right parallel shift arms 308 and cog pulley 310.

Cog pulley 310 receives a cog belt 408 from a motor not shown in FIGS. 8 and 9 which drives drive axle 302, but shown in FIG. 15 as propulsion motor 402.

Continuously variable speed transmission and steering differential 300 includes two major mechanisms namely shift mechanism 303 and differential mechanism 305.

First of all shift mechanism 303 includes speed change motor 320, chain 324, sprockets 322, motor sprockets 326 shift arm cap 362 and shift arm base 363.

Speed change motor 320 receives signals from an operator to rotate motor sprocket 326 which in turn moves chain 324 and sprockets 322 which in turn rotate ball screw shafts 311 which in turn simultaneously moves shift arms 308 thereby controlling the width or the spacing between the moveable drive sheaves 304 and the fixed drive sheaves 306 thereby effecting gear changes.

The reader will note that there are two moveable drive sheaves 304 on both the right and left side of the continuously variable speed transmission and steering differential 300.

By bringing shift arms 308 in closer proximity to each other by turning ball screw shafts 311 one can narrow the width between the moveable drive sheaves and the fixed drive sheaves 306 thereby increasing the gear ratio between the drive axle 302 and the right and left driven axles 340 and 342.

One can lower the gear ratio by reversing the direction of rotation of speed change motor 320 which in turn separates the left and right shift arms 308 thereby increasing the distance between the moveable drive sheaves 304 and the fixed drive sheaves 306. Low gear for example is shown in FIG. 8 and high gear is shown in FIG. 11. In FIG. 11 for example the drive sheaves are as close as possible together putting the continuously variable speed transmission and steering differential into the highest gear possible which would in turn provide for the highest speed at the driven axles 340 and 342. Referring now to FIG. 8 the reader will note that the drive sheaves 304, 306 are at their maximum separation which is accomplished by moving the parallel shift arms 308 away from each other in the lateral direction 333 using the shift mechanism 303 as described above. In low gear as shown in FIG. 8 the right driven axle 340 and the left driven axle 342 are turned at their lowest speed possible in other words the continuously variable speed transmission and steering differential 300 is in the lowest gear and/or low gear. Therefore moving the drive sheaves apart lowers the gear reduction to the driven axles 340 and 342 and moving the drive sheaves together increases the gear ratio to the right driven axle 340 and 342.

The reader will note that during the speed change operation shift mechanism 303 simultaneously moves both the left and right shift arms in unison in other words the separation between the moveable drive sheaves 304 and the fixed drive sheaves 306 on both the left and right side remains the same. The amount of speed change will be the same on both the right driven axle 340 and the left driven axle 342.

A differential mechanism shown generally as 305 includes the following major components namely a differential arm 312 which is connected to a link arm 314 at the link arm pivot 318 which in turn is connected to left and right differential links 316 which in turn is connected to shift arms 308. Differential arms 312 are connected to a differential arm shaft 319 and rotate in unison.

By rotating differential arm shaft 319 either clockwise or counter clockwise this in turn will move shift arms 308 either to the left and/or to the right thereby increasing the distance between the moveable drive sheave 304 and the fixed drive sheave 306 on one side, for example the right side, and decreasing the distance between moveable drive sheave 304 and fixed drive sheave 306 on the other side namely the left side of the transmission.

Differential arm shaft 319 which is in turn connected to front and back differential arms 312 is rotated at steering link point 321 through a series of links namely steering linkage 404 which ultimately is connected to either a set of handle bars 406 and/or steering wheel.

On the driven side of the continuously variable speed transmission and steering differential 300 there is a right driven axle 340, a left driven axle 342, a right fixed driven sheave 344, a right moveable driven sheave 348, a left fixed driven sheave 346 and a left moveable driven sheave 350 having a V-belt 352 mounted thereon. The reader will note that in regard to the drive sheaves the inner drive sheaves are the fixed drive sheaves 306 wherein the out drive sheaves are the moveable drive sheaves 304.

On the driven end the reader will note that it is the exact opposite namely the moveable driven sheaves 348 and 350 are on the inside and the right and left fixed driven sheaves 344 and 346 are on the outside. In this manner one is able to maintain belt alignment between the drive sheaves and the driven sheaves when changing gear ratios. The reader will also note that the V belt 352 connecting the drive sheaves to the driven sheaves is of constant length and therefore as the width of the drive sheaves increases the width of the driven sheaves decreases in order to maintain the correct tension on V belt 352.

FIG. 8 for example shows maximum separation between the fixed drive sheave 306 and the moveable drive sheave 304 which would correspond to the lowest gear possible whereas the right fixed driven sheave 344 and right moveable driven sheave 348 are shown in the closest spacing possible again corresponding to the lowest gear ratio. In other words FIG. 8 shows the shift mechanism 303 in the lowest gear ratio. FIG. 11 shows the sheaves 304 and 306 as close as possible and in a high gear position.

FIG. 8 also shows that the two sets of drive sheaves namely the right and left moveable drive sheaves 304 and fixed drive sheaves 306 are equally spaced meaning that there is no differential or steering input and therefore the differential is neutral or in the straight ahead position. In order to input steering one would urge steering link point 321 either left or right which in turn would turn differential arm shaft 319 which in turn would turn differential arms 312 which in turn would move shift arms 308 either to the right or to the left thereby inputting steering function. FIG. 12 shows maximum left turn differential input. The reader will note that in FIG. 12 the drive sheaves on the left hand side are in the lowest gear possible and the drive sheaves on the right hand side are in the highest gear possible therefore the right driven axle 340 will be turning at the maximum speed possible and the left driven axle 342 will be driven at the lowest speed possible therefore this will cause the vehicle to turn in a left hand turn since the right driven axle 348 is turning at a much greater speed than the left driven axle 342 thereby pivoting the vehicle to the left. In order to initiate a right hand turn the differential arm 312 would be pivoted in the opposite direction as shown in FIG. 12 and the gear ratios that are shown in FIG. 12 would essentially be reversed namely the right hand drive sheaves would be caused to become wider therefore putting it into a lower gear whereas the left drives sheaves would be brought closer together thereby putting them into a high gear such that the left driven axle 342 would be moving at a greater speed than the right driven axle 340 thereby pivoting the vehicle right creating a right hand turn.

There is further anti-rotation and suspension axles 332 which have a double function first of all provide for attachments to the rear suspension and also prevent rotation of the continuously variable speed transmission and steering differential structure.

Referring now to FIG. 9 which is a partial schematic cross-sectional view taken through the centre of drive axle 302 which shows that moveable drive sheave 304 is attached to drive axle 302 with a keyed torque hub 374 which includes hub rollers 360.

Drive axle 302 is mounted onto drive axle bearing 331 and also bearings 330 on each end of the shaft. Sliding bushings 370 are mounted onto drive axle 302 and slide in the longitudinal direction 309 along drive axle 302 as required.

Ball screw shafts 311 are mounted on to shift arms 308 with ball screw bearings 313.

Additionally drive axle 302 is also supported by centrally located drive axle bearing 372.

It should be apparent to persons skilled in the arts that various modifications and adaptation of this structure described above are possible without departure from the spirit of the invention the scope of which defined in the appended claim. 

I claim:
 1. A continuously variable speed transmission and steering differential comprising: a. a laterally extending central drive axle rotatably driven by a power source; b. two pairs of drive sheaves namely a left and right pair, mounted to the drive axle; wherein each pair of drive sheaves includes a fixed drive sheave and a laterally moveable drive sheave along the drive axle; c. a means for transmitting rotational energy from the left drive sheaves to a left driven axle and from the right drive sheaves to a right driven axle; d. two spaced apart longitudinally extending shift arms connected to the moveable drive sheaves for controlling the positioning of the moveable drive sheaves; e. wherein narrowing or increasing the gap between the shift arms narrows or increases respectively the gap between each pair of drive sheaves and increases or decreases the gear ratio which increases or decreases the speed of the driven axles, thereby providing speed control; f. wherein shifting the shift arms either left or right varies the gear ratio between the left and right pair of sheaves which provides differential speed between the left and right driven axles thereby providing steering control; therefore speed control and steering control is simultaneously and independently effected by controlling the position of the shift arms.
 2. The continuously variable speed transmission and steering differential claimed in claim 1 further including; a. the transmitting means includes two pairs of driven sheaves namely a left and right pair, mounted to the left and right driven axles respectively rotationally connected to the left and right pair of drive sheaves respectively; b. wherein each pair of driven sheaves includes a fixed driven sheave and a moveable driven sheave such that the gap between the pair of driven sheaves laterally varies inversely proportionally to the gap of the pair of the corresponding drive sheaves.
 3. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the shift arms are longitudinally extending spaced apart parallel members.
 4. The continuously variable speed transmission and steering differential claimed in claim 3 wherein the shift arms are planar bars.
 5. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the shift arms are connected with at least one ball screw shaft extending perpendicular to the shift arms for controlling the lateral spacing between the shift arms by rotating the ball screw shaft.
 6. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the shift arms are connected with two spaced apart ball screw shafts extending perpendicular to the shift arms for controlling the lateral spacing between the shift arms by rotating the ball screw shafts.
 7. The continuously variable speed transmission and steering differential claimed in claim 5 wherein the ball screw shaft rotation is motor driven.
 8. The continuously variable speed transmission and steering differential claimed in claim 5 wherein the ball screw shaft is motor driven with sprockets mounted onto the end of each ball screw shaft and motor and inter-connected with a chain.
 9. The continuously variable speed transmission and steering differential claimed in claim 1 further including a pivoting differential arm shaft connected to each shift arm with differential links such that pivoting the differential arm shaft in one direction varies the gear ratio between the left and right pair of sheaves and pivoting in the opposite direction varies the gear ratio oppositely between the left and right pair thereby providing steering control.
 10. The continuously variable speed transmission and steering differential claimed in claim 9 wherein the differential arm shaft is connected to at least one differential arm which in turn is connected to a link arm pivoting about a link arm pivot, wherein each end of the link arm is connected to one end of a differential link thereby connecting the differential arm shaft to the shift arms.
 11. The continuously variable speed transmission and steering differential claimed in claim 2 wherein the inner drive sheaves are fixed and the outer drive sheaves are moveable, and the inner driven sheaves are moveable and the outer driven sheaves are fixed.
 12. The continuously variable speed transmission and steering differential claimed in claim 9 wherein differential arm connected to a steering linkage which in turn is connected to a steering control such that actuating the steering control pivots the differential arm thereby providing steering control.
 13. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the drive axle includes a cog pulley connected to a belt for receiving power from a power source.
 14. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the driven axles are connected to wheels.
 15. The continuously variable speed transmission and steering differential claimed in claim 1 wherein the driven axles are connected to tracks.
 16. The continuously variable speed transmission and steering differential claimed in claim 12 wherein the steering control is a set of pivoting handle bars.
 17. The continuously variable speed transmission and steering differential claimed in claim 13 wherein the power source is an internal combustion motor.
 18. The continuously variable speed transmission and steering differential claimed in claim 2 wherein the transmitting means further includes two v-belts rotationally connecting the left drive sheaves to the left driven sheaves and the right drive sheaves to the right driven sheaves. 